Post on 10-Mar-2020
International
OPEN ACCESS Journal
Of Modern Engineering Research (IJMER)
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 85|
Effect of Subzero Treatment on Microstructure and Material
Properties of EN24 Steel
K. M. B. Karthikeyan1, R. Gowtham Raj2, K. Dinesh3, K. Aravind Kumar4 1Assistant Professor, ², 3, 4 B. E students, Department of Mechanical Engineering,
St. Joseph’s College of engineering, OMR, Chennai, Tamilnadu, India
I. INTRODUCTION Cryogenic treatment is an added heat treatment technique over conventionally heat-treated materials. It
is an effective method to improve the engineering performance of steels [1] - [2]-[3]-[4]. Cryogenic treatments are
carried out in two aspect, the shallow cryogenic treatment (SCT) conducted at temperature between -75°C
(198°K) and -90°C (183°K), the deep cryogenic treatment (DCT) conducted at temperatures below -195°C [8].
The commonly used cryogenics are liquid nitrogen (-195.8°C), liquid helium (-269°C), liquid hydrogen
(-252.9°C), methane (-161.5°C) and solid carbon dioxide (-78°C). Cryogenic treatment increases the mechanical
properties of cutting tool materials, die materials and bearing materials such as hardness, toughness, tensile
strength, wear resistance and corrosion resistance [3]-[7]. The lifetime of material under mechanical wear, get
affected by the retained austenite present in it [1]-[7]. In working conditions there may be chances for micro
structural transformations of retained austenite into martensitic structure which causes parts to break due to
sudden brittleness. This investigation revealed the fact that the retained austenite present after conventional heat
treatment is reduced substantially by lowering the quenching temperature up to subzero temperature without
sacrificing hardness and toughness of the heat treated material.
II. LITERATURE REVIEW Cryogenic treatment reduces percentage of retained austenite into tempered martensitic structure
thereby increasing material resistance to wear [2]-[7]. Cryogenic treatment not only helps in microstructural
transformations (retained austenite to martensite) but also helps in improving the metallurgical structure [5]-[7].
For high carbon steels the retained austenite transformation to martensite structure, require deep cryogenic
treatment [1]-[2]-[7]. In this investigation, the shallow cryogenic treatment (SCT) on EN24 medium carbon steel
was conducted and the effect of SCT on material hardness and toughness was investigated. EN24
Abstract: Cryogenic treatment of steels has been widely used for enhancing mechanical properties
like hardness, toughness and stable metallurgical structure. Application such as gears, kicker rods,
bolts are made of medium carbon alloy steels like EN-24 steel. In these applications, percentage of
retained austenite has considerable effects on the life of the material. A comparative study on
conventionally heat-treated (CHT) and shallow cryogenic treated (SCT) EN-24 steel was done to
evaluate the effect of shallow cryogenic treatment (SCT) on hardness, toughness and the amount of
retained austenite present in the structure of EN24 steel. The microscopic structure of cryogenic
treated EN24 steel revealed the formation of carbides, both primary and secondary carbides. An
estimated amount of 15% retained austenite after CHT tempered condition was less than 2% after SCT
tempered condition. Tensile test fractography of subzero treated (SCT) specimen revealed ductile
fracture. The maximum hardness observed in case of SCT tempered samples was 415BHN, 15%
increase from CHT tempered samples. The maximum impact strength observed in case of SCT
tempered samples was 240kJ/m2, 11% increase from CHT tempered samples. Further SCT tempered
samples, tempered at 650°C resulted in ductility increase by 55% as compared to CHT tempered
samples without sacrificing hardness.
Index Terms: EN24 Steel, hardness, shallow cryogenic treatment, retained austenite, tensile test
fractography.
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 86|
(817M40T–Molybdenum steel) is a high tensile alloy steel known for its wear resistance and used for high
strength applications. EN24 steel is surface-hardened to enhance wear resistance by induction hardening or
nitriding processing. Application includes propeller or gear shafts; connecting rods; aircraft landing gear
components etc.
The EN24 specimens are kept in a sealed insulated container containing solid carbon dioxide known as
dry ice for a period of 24 hours. The temperature was maintained at -76°C (197°K). The directions followed
during the investigation are a) retained austenite during conventional heat treatment (CHT) process transforms to
martensitic structure after shallow cryogenic treatment (SCT) and b) increase in material hardness as an effect of
martensitic transformation imparted into the material due to cryogenic treatment.
III. PROCESS METHODOLOGY
A. Specimen preparation
Specimens were prepared as per ASTM standards from annealed EN24 alloy steel bar with nominal
material composition of C-0.35%, Mn-0.45%, Si-0.11%, Cr-0.91%, Ni-1.31%, Mo-0.21%. For comparative
study, two sets (CHT and SCT) of specimens with four samples under each treatment were prepared for standard
laboratory tests.
B. Conventional heat treatment
The specimens are first austenized at a temperature of 850°C and quenched in a gas-carburizing furnace
with neutral proportions of one-inch one hour soak condition. The specimens treated are free of quench cracks
imply a little or nil residual stress. After confirming, the as quenched hardness, specimens are either double
tempered (2T) or triple tempered (3T). The specimens are soaked for 90 minutes duration at temperatures of
450°C and 650°C followed by air-cooling at room temperature as shown in Fig. 1.
C. Shallow Cryogenic treatment
Shallow Cryogenic treatment is a supplement treatment to conventional heat treatment and it involves
three stages. Stage-1: Conventional heat treatment (CHT) and quenched, Stage-2: Subzero treatment (SCT at
-78°C) and Stage-3: Subzero treatment (SCT) followed by double or triple tempering process at temperatures
450°C and 650°C and cooled down at room temperature. Subzero treatment is carried in an insulated container
with solid CO2 at a temperature of -78°C and then bringing it to room temperature followed by tempering as
shown in Fig. 1.
Specimen
Preparation
Conventional Heat Treatment
Austenizing @850 C in Gas
Carburizing Furnace
Quenched in neutral Gas
Carburising Furnace
Shallow Cryogenic Treatment
for 24 hours in an insulated
container maintained at -78 c
Tempering @450 c at one inch
one hour soak condition, Soak
Period -90 minutes; Air cooled at
room Temperature
Tempering @650 c at one inch
one hour soak condition, Soak
Period -90 minutes; Air cooled at
room Temperature
Conventional Heat Treatment
(CHT)
Shallow Cryogenic Treatment
(SCT)
Tempering @450 c at one inch
one hour soak condition, Soak
Period -90 minutes; Air cooled at
room Temperature
Tempering @650 c at one inch
one hour soak condition, Soak
Period -90 minutes; Air cooled at
room Temperature
Fig. 1. Process flow chart
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 87|
IV. RESULTS AND ANALYSIS
A. Hardness Test
Hardness testing is widely used for material evaluation due to its simplicity and low cost relative to direct
measurement of many properties [9]. Hardness testing does not give a direct measurement of any performance
properties, hardness correlates with material strength, wear resistance and other mechanical properties [9]. The
annealed EN24 Steel sample has an equivalent hardness of 217BHN and the average hardness of the CHT
quenched samples was 363BHN. The maximum hardness observed in case of SCT tempered samples were
415BHN. There is a considerable increase in the hardness value of the subzero treated samples as compared to
conventionally heat treated and annealed EN24 Steel. The average value of hardness is tabulated for reference in
Table 1.
Table 1. Hardness test Results
Sl.
No Specimen
Hardness
(BHN)
Micro
Vickers
hardness
(HRC)
1 Annealed 217 239
2 CHT Tempered 363 388
3 SCT Tempered 415 465
B. Impact Test
The impact test was performed as per ASTM A370 (standard test method and definitions for mechanical
testing of steel products) to study the effect of cryogenic treatment on the toughness of EN-24 steel. The most
common test is the Charpy V-notch impact test, in which the standard specimen is struck opposite the notch by a
heavy falling pendulum. The toughness is expressed in terms of the kinetic energy absorbed by the fracture. The
result of tests revealed that conventional heat treated and quenched samples absorbed 17.5 joules of energy
whereas subzero tempered samples absorbed 24 joules. The average value of toughness is tabulated for reference
in Table 2.
Table 2. Toughness test Results
Sl.
No Description of samples
Impact
value
(Joules)
Impact
Strength
(KJ/m2)
1 CHT and quenched 17.5 175
2 CHT and tempered 21.50 215
3 SCT and tempered 24.00 245
C. Tensile test
Tensile test was performed on six different samples of EN24 steel. The test was done on annealed, CHT
quenched, CHT tempered at 450°C, SCT quenched, SCT tempered at 450°C and SCT tempered at 650°C. The
SCT samples are tempered under two different temperatures, 450°C and 650°C to understand its elastic and
elasto-plastic elongation. The tensile test was carried out according to ASTM A370-05. The test specimen
dimensions are presented in Fig. 2.
Fig. 2 Tensile Test Specimen
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 88|
From Table 3 it has been observed that the tensile strength of subzero treated samples is more than that
of the conventionally quenched and annealed samples. Tempering after subzero treatment at 450°C has lesser
elongation, greater ultimate strength, greater yield strength than tempering at 650°C. The experimental results
reveal that it is optimum to use tempering temperature scale at 450°C.
Table 3. Tensile Test Results
D. Graphical Analysis
Percent elongation is the ability of the material to flow plastically before facture. Even though there is no
proportional relationship between ductility and load carrying capacity of the material under elasto-plastic region,
yet the material of low percent elongation can withstand greater loads. From Table 3, SCT tempered EN24 steel
has least percent elongation in elasto- plastic region; it means that it can withstand greater loads compared to
CHT tempered EN24 steel. SCT tempered EN24 steel, tempered at 450°C has lesser elongation, greater ultimate
strength, greater yield strength and high ductility when compared to CHT tempered EN24 steel. The stress strain
curve for different material treatment condition is presented in Fig. 3.
Fig. 3. Stress strain curves –Comparative Trend
E. Tensile Test Fractography analysis using SEM
Broken tensile test samples were tested for fractography analysis. Test Sample made with cut section
diameter of 10 mm and length 20 mm molded using Bakelite. The specimen are ground progressively with finer
SiC water proof papers from 120 to 1000 grit to produce polished flat surface. The surface was etched using 2%
Nital and cleansed using alcohol. In CHT quenched specimen presences of voids are visualized. More over the
grain refinement is very small it means that the particles are coarse and load withstanding capacity will be less.
Fractography test of Annealed EN24 material as shown in Fig. 5, exhibits ductile fracture mode with
cracks and micro voids. The annealed material under heavy loads develops voids in the structure that prolongs
and collapse.
Sl.
No Specimen
Tensile
Strength
(MPa)
Yield
Strength
(MPa)
Elongat
ion
(%)
Reducti
on
(%)
1 Annealed specimen 849.95 759.04 15.60 59.04
2 CHT Quenched 2177.99 2095.58 10.00 39.88
3 CHT Tempered
@450°C 1580.16 1517.81 7.20 21.36
4 Subzero Quenched 2248.55 2158.45 10.40 37.83
5 Subzero Tempered
@450°C 1587.31 1550.29 4.80 23.44
6 Subzero Tempered
@650°C 1184.33 1098.79 11.20 29.56
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 89|
Fig. 4. Specimens before and after tensile testing
Fig. 5. SEM Fractography of Annealed EN24 material.
Fractography test for CHT tempered material as shown in Fig. 6, exhibits ductile fracture mode. It means
that due to elongation the material reduces its diameter and after yielding failure takes place. Dimples and hot tear
phenomenon are clearly seen in the surface, observed uneven breakage due to unevenly scattered carbides.
Fig. 6 SEM Fractography of CHT Tempered EN24 material
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 90|
Fractography test of SCT Tempered EN24 material as shown in Fig. 7, exhibits micro cracks, small in
size when compared to CHT quenched samples. The presence of dimples are negligible hence even fracture is
visible in the picture. Plastic flow prior to fracture was observed as shown in Fig.8. The secondary carbides
observed in the microstructure of SCT Tempered at 450°C as shown in Fig.11, increases the wear resistant
property of the material.
Fig 7. SEM Fractography of SCT Tempered EN24 material
Fig 8. SEM Fractography of SCT Tempered EN24 material Showing Plastic Flow behavior before fracture
F. Microscopic study
The test samples for micro examination grounded using different grades of emery papers (200, 400, 800,
and 1200) then polished using diamond paste. It is cleansed using etchant Nital 2% and allowed to dry. The
microstructure was examined using Optical Microscope. Fig.9 shows the microstructure of annealed EN24 Steel
revealing fine pearlite matrix structure.
Fig 9. Microstructure of annealed En-24 steel, Mag: 500X
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 91|
The microstructure of steel at conventionally heat treated condition as shown in Fig.10 reveals an
estimated amount of the retained austenite was 15%. The microstructure in Fig.10 where more of white spots
(retained austenite) present is responsible for the decrease in the hardness value of the specimen.
Fig 10. Microstructure of CHT and quenched En-24 steel
Fig 11. Microstructure of SCT Tempered at 450°C
For subzero treated sample the retained austenite present was observed to be less than 2%. The retained
austenite found as shown in Fig.11 are scattered and the presence of secondary carbides on the surface are evident.
Secondary carbides formed mainly due to transformation of retained austenite particles to temper martensitic.
V. CONCLUSIONS The comparative study made on the effect of cryogenic treatment on EN-24 steel revealed the following:
A substantial improvement in hardness from 363BHN for conventionally heat treated (CHT) material to
415BHN for subzero treated (SCT) material.
A substantial improvement in toughness of material from 17.5 Joules in case of annealed sample to 24 Joules
in case of SCT sample.
A substantial improvement in ultimate tensile strength in case of SCT EN24 steel with decrease in
percentage elongation. The tensile strength and yield strength of SCT tempered samples depicted marginal
improvement than CHT tempered samples, tempered at 450°C, but percentage elongation for SCT tempered
samples reduced by 50% compared to CHT tempered samples.
The Tensile test fractography study indicates the mode of failure was ductile in each case.
Presence of retained austenite from 15% in case of conventionally heat treated condition has been reduced to
less than 2% in case of subzero treatment.
The mechanical testing of shallow cryogenically treated EN24 carbon steel material exhibited increase
in mechanical properties like hardness, toughness and substantial reduction in percentage of retained austenite.
Effect of Subzero Treatment on Microstructure and Material Properties of EN24 Steel
| IJMER | ISSN: 2249–6645 | www.ijmer.com | Vol. 4 | Iss.11| Nov. 2014 | 92|
VI. ACKNOWLEDGEMENT The authors acknowledge the services M/s.Micro- Hard Processing-Heat Treatment, Ambattur,
M/s.Microlab, Ambattur Industrial Estate, and St. Joseph’s College of Engineering, OMR, Chennai, Tamilnadu,
to encourage us to carry out a part of this research.
REFERENCES [1] Lukwinder Pal Singh, Jagtar Singh, “Effects of Cryogenic Treatment on High Speed Steel Tools,” Journal of
Engineering and Technology, vol. 14, issue 2, pp.88-93, July –December 2011.
[2] P. I. Patel, R. G. Tated, “Comparison of Effects of Cryogenic Treatment on Different Types of Steels: A Review”,
International Conference in Computational Intelligence (ICCIA) 2012, Published by IJCA Journal, ICCIA- Number 9,
March 2012
[3] Harpreet Singh, Er.B.S.Ubhi and Er. Harvinder Lal, “Improvement in the Corrosion Rate and Mechanical Properties
of Low Carbon Steel through Deep Cryogenic Treatment”, International Journal of Scientific and Technology
Research, volume 2, issue 6, pp.10-29, June 2013
[4] Ajit Behera, S.C. Mishra, “Comparitive Study of Cryo-Treated Steel”, International Journal of Scientific and
Technology Research, volume 1, issue 7, pp.46-48, August 2012
[5] Kamran Amini, Said Nategh, Ali Shafiey and Mohhamad Ali Solanty, “To Study the Effect of Cryogenic Heat
Treatment on Hardness and the amount of Residual Austenite in 1/2304 Steel”, Metal, volume 13, pp.1-7, May 2008
[6] D.Candane, N.Alagumurthi and K.Palaniradja, “Tribological Studies on Deep Cryogenic Treated AISI T42 High
Speed Steel using Response Surface Methodology”, Advances in Materials, volume 2(2), pp.12-22, April 2013
[7] D. Candane, N.Alagumurthi and K.Palaniradja, “Effect of Cryogenic Treatment on Microstructure and Wear
Characetristics of AISI M35 HSS”, International Journal of Materials Science and Applications, volume 2(2),
pp.56-65, March 2013
[8] Dr.Abbas A Hussein, Murtadha Qasim Idan Alkinani, “Effect of Cryogenic Treatment on the Properties of Low
Carbon A858 Steel, Journal of Engineering, pp.837-843, volume 18, July 2012
[9] Handbook of Analytical Methods for Materials, Materials Evaluation and Engineering, Inc, pp.35. http://mee-inc.com/